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Time From the Perspective of a Particle Physicist

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Friction between the Earth and the Moon (seen daily in tides) ... Moon receeding from the Earth by 4 cm each year. 500,000,000 years ago there were ... – PowerPoint PPT presentation

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Title: Time From the Perspective of a Particle Physicist


1
Time From the Perspective of a Particle Physicist
  • David Hedin
  • Department of Physics
  • August 8, 2001

2
Outline
  • Time in our everyday lives
  • Looking back in time - examples from Astronomy
  • Looking back in time - examples from high energy
    accelerators

3
Markers of Time
  • DAY Sun at maximum height
  • MONTH length of time it takes for the moon to
    make an orbit around the Earth (repeats phase
    every 29.5 days)
  • Most early cultures use the day and month to mark
    time
  • moon-month-measure-man may all have the same
    root

4
Length of Day and Month are changing
  • Friction between the Earth and the Moon
    (seen daily in tides)
  • Day becomes .002 seconds longer each century
  • Moon receeding from the Earth by 4 cm each year
  • 500,000,000 years ago there were
  • 22 hours in a day
  • 400 days in a year
  • Billions of years in the future there will be
  • 1 day 47 present days
  • 1 month 1 day
  • Earth-Moon frozen into a pair with no additional
    spin for the Earth alone

5
The Year
  • Two Indicators
  • Due to the Earths tilt the
  • Length of the Day and
  • Suns path through the sky
  • vary. One year returns to the same spot
  • More dramatic further north (Stonehenge)
  • Which stars are overhead changes with seasons.
    Gives passage of year
  • Passage of time at night also given by stars
    apparent motion
  • Stars Calendar and Clock

6
Star Wheel
  • Stars move East to West over the course of one
    Night (in circle about the North Star)
  • Stars move East to West by 2 hours per month
    and return to the same position after one Year
  • just Earths daily spin and yearly orbit about
    the Sun

7
What Year Is It?
  • Almost all societies agree - 2001
  • But where should time really start?
  • Formation of Earth 4.5 billion years ago
  • Formation of Sun 5.0 billion years ago
  • Sun will continue as a star for another
  • 5 billion years and then transform into
  • a Red Giant and then a White Dwarf.
  • The Sun orbits the center of the Milky
  • Way galaxy every 250 million years
  • So now in the 20th galactic year
  • Formation of Universe 13 billion years ago

8
365.242 days in a year
  • Ancient calendars were Lunar
  • Babylon - 12 months 6 with 29 days and 6 with
    30. Add 13th month occasionally (also used in
    India and similar in China)
  • Egypt - 12 months each 30 days plus 5 extra
  • Polynesia - 13 lunar months drop 1 occasionally
  • Priests would determine when to add extra months
    and day
  • Very tempting to have 360 days in a year and 12
    months of 30 days. nice numbers
  • Lack of correlation between day-month-year
    bothered philosophers and theologians.
    Understanding this random motion (and the
    planets were even worse) by Copernicus, Kepler,
    Galileo, Newton gave us modern science

9
365.242 days in year
  • If normal year has 365 days need extra 24
    days/century and extra 2 days/millenium
  • 46 BC Julius Ceaser (really Sogigula an Egyptian)
    - Julian calendar with leap day every 4 years.
    But 8 too many days every 1000 years so.
  • Gregorian calendar adopted
  • Spain and Catholic Europe 1582
  • England
    1751
  • Russia
    1918
  • which immediately skipped 10 days (in 1582).
    No leap day on century years 1700,1800,1900,2100,2
    200 (just those divisible by 400)

10
Time in Astronomy
  • Lives of Stars
  • stars are born in interstellar gas clouds
    and die once they have exhausted their nuclear
    fuel
  • more massive stars burn their fuel faster
    and may only exist for 1 million years while
    stars like our Sun (or smaller) will exist for 10
    billion years or longer
  • Clusters of Stars
  • stars are formed in groups with some massive
    and some small. The size of the largest stars in
    the cluster tells us how old all the stars in
    that cluster are.
  • The oldest clusters are formed from the
    primordial material of the Universe (before stars
    existed) and their atomic composition is a fossil
    record from the first few minutes after the
    Universe was created

11
Galaxies
  • Stars come in groups of 200 billion or more like
    our own Milky Way Galaxy
  • as they are so bright galaxies can be seen if if
    extremely far away - 5 billion light years
  • as light takes time to travel to us, looking at
    galaxies very far away means we are looking back
    in time. Soon the latest telescopes will have
    study more and more galaxies from the time when
    they (and the stars they contain) were first
    formed

12
Galaxies and Hubbles Law
  • It has been observed (first by Hubble in the
    1920s) that galaxies are moving away from us and
    that the further away they are the faster they
    are moving (vHd)
  • Indication that the Universe is expanding, and it
    has been ever since it was created in the Big
    Bang about 13 billion years ago
  • Understanding how the expansion rate changes with
    time tells us about the inherent mass and energy
    which makes up the Universe, a more precise
    values for its age, and what its fate will be
  • Current data is perplexing most of the mass is
    missing and due to some unexplained new types
    of matter and there is vacuum energy which is
    acting like a kind of anti-gravity and
    accelerating the expansion

13
More on Hubbles Law
  • As the Universe expands it cools down. At its
    earlier times it was much, much hotter.
  • If the Universe keeps on expanding forever
    everything will come to a cold end, the stars
    will all end there lives and no new ones will be
    formed
  • if the expansion stops and a contraction begins
    the Universe will heat up as it returns to a
    state similar to when it was formed
  • Not unambiguously known what fate will be

14
Fire and IceRobert Frost - 1923
  • Some say the world will end in fire,
  • Some say in ice.
  • From what Ive tasted of desire
  • I hold with those who favor fire.
  • But if I had to perish twice,
  • I think I know enough of hate
  • To say that for destruction ice
  • Is also great
  • And would suffice.

15
Exploring Very Early Times
  • Fossil evidence available to astronomy are
    remnants from the first few minutes after the Big
    Bang
  • To explore back to earlier times we use our
    understanding of physics
  • The earlier you go in time the hotter was the
    Universe. Particle accelerators can briefly
    reproduce those conditions. The highest energy
    machine is equivalent to about 1 picosecond
    (.000000000001) after the universe began
  • Even earlier times can be understood by
    extrapolating symmetries in Nature but going back
    to the moment of Creation needs a complete
    knowledge of gravity and a more complete
    understanding of time itself

16
Fermilab
  • Worlds highest energy particle accelerator (2
    TeV 2 trillion electron volts
    2,000,000,000,000 eV total energy)
  • collides protons with antiprotons
  • located in Batavia - take I88 (or Rt 38) to Kirk
    Road (just east of toll booth then a few miles
    north on Kirk)
  • VISITORS WELCOMED
  • self-guided tour plus videos in main building
  • Education center
  • Nature trails and fishing
  • Buffalo herd

17
Fermilab Accelerator - 2 TeV Energy
Tevatron Ring(1 km radius)
CDF
D0
Main Injector Ring
18
Matter-Antimatter Asymmetries
  • We live in a world which is dominated by matter
    such as protons and electrons (but antimatter is
    readily made at accelerators and has some medical
    applications)
  • But the very early universe had equal amounts of
    both matter and antimatter. After most
    annihilated with each other a very, very, very
    small excess of matter was left over to make
    everything including us
  • WHY????

19
Matter-Antimatter continued
  • Matter-antimatter differences have also been
    observed in the decay of the strange quark (1964)
    and the bottom quark (2001)
  • the underlying math which describes quarks shows
    that if there are at least 3 generations of
    quarks then you can have an asymmetry (which is
    why we are all very happy that the top and bottom
    quark exist!!)
  • Still missing is a Theory of Everything which
    explains why there are three generations. (Carl
    Albright of NIU is working on it.) This ToE
    probably also explains mass differences
  • Ongoing experimental efforts (including neutrino
    studies) gives constraints which theorists like
    Albright use as a guide in selecting models of
    the ToE

20
Why is Gravity so Weak?
  • The Weak, Strong, and Electromagnetic Forces all
    have about the same strength at Fermilabs energy
    (though not at room temperature) and are well
    described by complete relativistic quantum
    mechanical theories
  • Gravity is much, much weaker. 37 orders of
    magnitude weaker than EM. Only dominates at
    larger distances as EM has both positive and
    negative charges and others are short-ranged
  • No complete theory of gravity exists. Einstein
    tried for one and this is Stephen Hawkings
    primary work. Will be necessary to understand the
    very, very early universe when all 4 forces had
    the same intrinsic strength

21
Weakness of Gravity II
  • Need new theories, two of which are Supersymmetry
    and Extra Dimensions
  • Supersymmetry (SUSY)
  • postulates the existence of extra particles,
    which are partners to existing (selectrons
    partner to electrons, etc)
  • All particles produced similarly in the very
    early universe. All forces also the same at that
    time
  • As Universe cools during first picosecond SUSY
    particles freeze out as they are heavier. Their
    existence helps to explain gravitys weakness
    (though not completely)
  • SUSY particles could explain missing mass
    observed in astronomy

22
Weakness of Gravity III Extra Dimensions
  • Lets assume (for fun) that we live in an
    11-dimensional world
  • time
  • normal 3-D position space
  • 7 extra dimensions which are small
    (compactified is the physics term) less than 1
    mm
  • Only gravity can communicate to the extra
    dimensions (all other particles and forces are
    confined to the normal 3D space)
  • Fairly simple geometry explains why gravity
    appears weak - it has to spread its force fields
    over a larger space which thereby dilutes them in
    the normal 3D space itself

23
CONCLUSIONS
  • The understanding of the motion of the Sun, moon,
    and planets - which are day-to-day indicators of
    time - lead to the development of first astronomy
    and then physics
  • By both studying the fossil record in stars
    and elsewhere and actually looking back in time
    by analyzing distant objects, astronomers have
    mapped out most of the Universes history from
    the Big Bang to today. Though the ultimate fate
    is still uncertain.
  • To understand the first instances of time
    requires an understanding of Natures underlying
    particles and forces. There is not yet a Theory
    of Everything but we are working on it.
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